DE102015201045A1 - High voltage transistor operable with a high gate voltage - Google Patents

Abstract

A semiconductor device (1) is presented. The semiconductor device (1) comprises a first load contact (11), a second load contact (13) and a semiconductor region (12) positioned between the first load contact (11) and the second load contact (13). The semiconductor region (12) includes the following: a first semiconductor contact region (121), the first semiconductor contact region (121) being in contact with the first load contact (11); a second semiconductor contact zone (123), the second semiconductor contact zone (123) being in contact with the second load contact (13); a semiconductor drift zone (122), wherein the semiconductor drift zone (122) is positioned between the first semiconductor contact zone (121) and the second semiconductor contact zone (123) and doped with first dopants of a first conductivity type, the semiconductor drift zone (122) defining the first semiconductor contact zone (121). coupled to the second semiconductor contact zone (123). The semiconductor device (1) further includes: a trench (14) extending into the semiconductor region (12) along an extending direction (Y) facing from the first semiconductor contact region (121) to the second semiconductor contact region (123) the trench (14) comprises a control electrode (141) and an insulator (142), wherein the insulator (142) isolates the control electrode (141) from the semiconductor region (12). The control electrode (141) extends within the trench (14) along the extension direction (Y) at least as far as 75% of the total extension of the semiconductor drift zone (122) in the extension direction (Y). The semiconductor drift zone (122) has a drift zone doping concentration of first dopants, wherein the drift zone doping concentration and the total extension of the semiconductor drift zone (122) define a reverse voltage of the semiconductor device (1). The insulator (142) is designed to insulate a voltage that is at least 50% of the reverse voltage.

Description

TECHNICAL AREA

This specification relates to embodiments of semiconductor devices, to embodiments of circuit arrangements that include a semiconductor device, and to embodiments of methods of controlling a semiconductor device. In particular, this specification relates to embodiments of a power semiconductor device that can be operated with a high gate voltage.

GENERAL PRIOR ART

Many functions of modern devices in automotive, consumer and industrial applications, such as converting electrical energy and driving an electric motor or electric machine, depend on semiconductor devices. Insulated Gate Bipolar Transistors (IGBTs), Metal Oxide Semiconductor Field Effect Transistors (MOSFETs), and diodes have been used, for example, for a wide variety of applications including, but not limited to, switches in power supplies and power converters.

On the other hand, occasionally mechanical switches are still used in the field of load management circuits. A mechanical switch, such as a relay or a so-called contactor, may be used, for example, to electrically connect a load to a power supply, such as a battery or a mains connection, or to disconnect the load from the power supply. Sometimes such a switch is also referred to as a "master switch" or as a "master switch".

BRIEF SUMMARY OF THE INVENTION

According to one embodiment, a semiconductor device is provided. The semiconductor device includes a first load contact, a second load contact, and a semiconductor region positioned between the first load contact and the second load contact. The semiconductor region includes a first semiconductor contact zone, wherein the first semiconductor contact zone is in contact with the first load contact; a second semiconductor contact zone, wherein the second semiconductor contact zone is in contact with the second load contact; a semiconductor drift zone, wherein the semiconductor drift zone is positioned between the first semiconductor contact zone and the second semiconductor contact zone and doped with first dopants of a first conductivity type, the semiconductor drift zone coupling the first semiconductor contact zone to the second semiconductor contact zone. The semiconductor device further includes a trench extending into the semiconductor region along an extending direction that faces from the first semiconductor contact zone to the second semiconductor contact zone, the trench including a control electrode and an insulator, the insulator isolating the control electrode from the semiconductor region. The control electrode extends within the trench along the extension direction at least as far as 75% of the total extension of the semiconductor drift zone in the extension direction. The semiconductor drift zone has a drift zone doping concentration of first dopants, wherein the drift zone doping concentration and the total extension of the semiconductor drift zone define a reverse voltage of the semiconductor device. Furthermore, the insulator is designed to insulate a voltage that is at least 50% of the reverse voltage.

According to a further embodiment, a circuit arrangement is presented. The circuitry includes a power supply, the power supply having a first power output and a second power output and configured to provide an output voltage greater than 40V between the first power output and the second power output; a load current path, the load current path configured to couple a load to the first power output and to the second power output; a semiconductor device included in the load current path, the semiconductor device comprising a control terminal, a first load terminal, and a second load terminal, the semiconductor device arranged to be serially connected to the load by the first load terminal and the second load terminal; a control current path, the control current path connecting the power supply to the control terminal; a controllable switch included in the control current path, the controllable switch configured to receive a switch control signal and, in response to the switch control signal, to electrically connect the control terminal to either the first power output or the second power output.

In accordance with yet another embodiment, a method for controlling a semiconductor device is presented. The semiconductor device to be controlled includes a first load contact, a second load contact, and a semiconductor region positioned between the first load contact and the second load contact. The semiconductor region includes a first semiconductor contact zone, wherein the first semiconductor contact zone is in contact with the first load contact; a second semiconductor contact zone, wherein the second semiconductor contact zone is in contact with the second load contact; a semiconductor drift zone, wherein the semiconductor drift zone is positioned between the first semiconductor contact zone and the second semiconductor contact zone and is doped with first dopants of a first conductivity type, the semiconductor drift zone coupling the first semiconductor contact zone to the second semiconductor contact zone. The semiconductor device further includes a trench extending into the semiconductor region along an extending direction that faces from the first semiconductor contact zone to the second semiconductor contact zone, the trench including a control electrode and an insulator, the insulator isolating the control electrode from the semiconductor region. The control electrode extends within the trench along the extension direction at least as far as 75% of the total extension of the semiconductor drift zone in the extension direction. Furthermore, the semiconductor drift zone has a drift zone doping concentration of first dopants, wherein the drift zone doping concentration and the total extension of the semiconductor drift zone define a reverse voltage of the semiconductor device. The method includes providing a gate control signal having a voltage that is at least 50% of the reverse voltage to the control electrode.

Additional features and advantages will become apparent to those skilled in the art upon reading the following detailed description and upon considering the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The parts in the figures are not necessarily to scale; instead, emphasis is placed on illustrative principles of the invention. Moreover, like reference characters designate corresponding parts throughout the figures. In the drawings illustrates:

1 schematically a portion of a vertical section through a semiconductor device according to one or more embodiments;

2 schematically a portion of a vertical section through a semiconductor device according to one or more embodiments;

3A schematically a portion of a vertical section through a semiconductor device according to one or more embodiments;

3B schematically a portion of a horizontal section through a semiconductor device according to one or more embodiments;

4 schematically a portion of a vertical section through a semiconductor device according to one or more embodiments;

5A schematically a circuit diagram of a circuit arrangement according to one or more embodiments;

5B schematically a circuit diagram of a circuit arrangement according to one or more embodiments;

6 schematically a circuit diagram of a circuit arrangement according to one or more embodiments.

DETAILED DESCRIPTION

In the following detailed description, reference is made to the accompanying drawings, which form a part hereof, and in which is shown by way of illustration specific embodiments in which the invention may be practiced.

In this regard, directional terminology such as "upper," "bottom," "below," "forward," "behind," "back," "leading," "appending," etc. is used with reference to the orientation of the figures described. Because portions of embodiments may be positioned in a variety of orientations, the directional terminology is used for purposes of illustration and is in no way limiting. It is understood that other embodiments may be utilized and structural or logical changes may be made without departing from the scope of the present invention. The following detailed description is therefore not to be considered in a limiting sense, and the scope of the present invention is defined by the appended claims.

Reference will now be made in detail to various embodiments, one or more examples of which are illustrated in the figures. Each example is provided by way of explanation and is not intended to limit the invention. Features that are illustrated or described as part of one embodiment may be applied to, for example, or in combination with other embodiments to provide a further embodiment. The present invention is intended to include such changes and variations. The examples are described using a specific language that is not to be construed as limiting the scope of the appended claims. The drawings are not to scale and are for illustrative purposes only. For the sake of clarity, the same elements or manufacturing steps have been identified by the same reference numerals in the various drawings, unless otherwise specified.

The term "horizontal" as used in this specification is intended to describe an alignment parallel to a horizontal surface of a semiconductor substrate or a semiconductor region. This may be, for example, the surface of a wafer or a chip.

The term "vertical" as used in this specification is intended to describe an orientation that is substantially perpendicular to the horizontal surface, i. parallel to the normal of the surface of the semiconductor substrate or the semiconductor region.

In this specification, n-doped may be referred to as a "first conductivity type", whereas p-doped may be referred to as a "second conductivity type". Alternatively, opposing doping relationships may be applied so that the first conductivity type may be p-doped and the second power type may be n-doped. For example, an n-doped semiconductor region may be produced by inserting donors into a semiconductor region. Further, a p-type semiconductor region may be produced by inserting acceptors into a semiconductor region.

In the context of the present specification, the terms "in ohmic contact", "in ohmic connection" and "electrically connected" are intended to describe that there is a low resistance electrical connection or a low resistance current path between two regions, sections, portions or parts of a Semiconductor device or between different terminals of one or more devices or between a terminal or a metallization or an electrode and a portion or part of a semiconductor device. Further, the term "in contact" in the context of this specification is intended to describe that there is a direct physical connection between two elements of the corresponding semiconductor device; e.g. For example, a transition between two elements in contact with each other may not include another intermediate element or the like.

Specific embodiments described herein are, but are not limited to, embodiments of a power semiconductor device, such as a monolithically integrated MOSFET, e.g. a monolithically integrated power MOSFET, which may be operated as a master switch, or, respectively, as a main switch for connecting a load to a power supply and disconnecting the load from the power supply, e.g. The following may include: a battery that provides a DC voltage, a charge pump that provides a DC voltage, a power supply that provides an AC voltage, an inverter circuit that provides an AC voltage, or a rectifier circuit that provides a DC voltage.

The term "power semiconductor device" as used in this specification is intended to describe a semiconductor device on a single chip with high voltage blocking and / or high current routing capabilities. In other words, the power semiconductor devices are intended for high current, such as in the ampere range of e.g. up to several amps, and / or high voltages, such as above 40V, 100V and above.

The 1 and 2 schematically illustrate a portion of a vertical section through a semiconductor device 1 according to some embodiments. The following will both on 1 like on 2 Referenced.

The semiconductor device 1 includes a first load contact 11 which may be a so-called source contact. On the opposite side comprises the semiconductor device 1 a second load contact 13 which may be a so-called drain contact. Between the first load contact 11 and the second load contact 13 is a semiconductor region 12 arranged. The semiconductor region 12 may be configured to conduct a load current from the first load contact 11 to the second load contact 13 and / or in the opposite direction, ie from the second load contact 13 to the first load contact 11 ,

The semiconductor region 12 includes a first semiconductor contact zone 121 , which are in contact with the first load contact 11 located. A second semiconductor contact zone 123 which are also part of a semiconductor region 12 is in contact with the second load contact 13 ,

The semiconductor region 12 further includes a semiconductor drift zone 122 between the first semiconductor contact zone 121 and the second semiconductor contact zone 123 is positioned. The semiconductor drift zone 122 is doped with first dopants of a first conductivity type. The semiconductor drift zone 122 is, for example, an n ^- doped semiconductor zone.

The semiconductor drift zone 122 couples with the first semiconductor contact zone 121 to the second semiconductor contact zone 123 , The semiconductor contact zones 121 and 123 may also be doped with dopants, with reference to FIGS 3A and 4 will be explained in more detail.

The semiconductor device 1 further includes a trench 14 that stretches along one Extension direction Y, which from the first semiconductor contact zone 121 to the second semiconductor contact zone 123 shows, in the semiconductor region 12 extends.

For example, the first load contact 11 at the front of the semiconductor device 1 arranged and the second load contact 13 is at the back of the semiconductor device 1 arranged. Thus, the extension direction Y may be parallel to the vertical or the horizontal. In other words, the extension direction may be substantially parallel to a direction of an electric field caused by a voltage difference between the first load contact 11 and the second load contact 13 is caused.

The ditch 14 includes a control electrode 141 and an insulator 142 , The insulator 142 isolates the control electrode 141 from the semiconductor region 12 , The insulator 142 For example, it includes a dielectric material.

As in 1 and 2 is schematically illustrated, the control electrode extends 141 within the trench 14 along the extension direction Y at least as far as about 75% of a total extension of the semiconductor drift zone 122 in the extension direction Y. In accordance with the in 1 and 2 illustrated examples, the control electrode extends 141 even more than 100% of the total extension of the semiconductor drift zone 122 ,

In addition, the semiconductor drift zone exhibits 122 a drift zone doping concentration of first dopants, wherein the drift zone doping concentration and the total extension of the semiconductor drift zone 122 a reverse voltage of the semiconductor device 1 define.

For example, the reverse voltage of the semiconductor device 1 a reverse voltage between the first load contact 11 and the second load contact 13 , In an embodiment, the semiconductor device 1 by supplying a gate control signal to the control electrode 141 controlled, eg switched on and off. For example, such a gate control signal may be generated by generating a voltage difference between the control electrode 141 and the first load contact 11 or accordingly by generating a voltage difference between the control electrode 141 and the second load contact 13 to be provided. Accordingly, the voltage of the gate control signal may be a so-called gate-source voltage or, correspondingly, a gate-drain voltage. For example, the semiconductor device 1 be switched on or off by varying the voltage of the gate control signal.

The semiconductor device 1 may be designed to carry the load current when in an on state. The semiconductor device 1 can be used to block the flow of a load current when in an off state, as long as the voltage between the first load contact 11 and the second load contact does not substantially exceed the reverse voltage, be designed. As a result, the term "reverse voltage" can be applied to a minimum breakdown voltage of the semiconductor device 1 , eg to a minimum drain-source breakdown voltage. For example, even if the semiconductor device 1 is operated in the off state, a flow of a load current can not be locked if the voltage between the first load contact 11 and the second load contact 13 significantly exceeds the blocking voltage.

The insulator 142 may be designed to insulate a voltage that is at least 50% of the reverse voltage. In other words, the insulator can 142 have an insulation voltage that is at least 50% of the reverse voltage. Thereby, according to an embodiment, the gate control signal, that of the control electrode 141 eg by generating a voltage difference between the control electrode 141 and the first load contact 11 or accordingly by generating a voltage difference between the control electrode 141 and the second load contact 13 can be supplied with a voltage which is at least 50% of the reverse voltage.

For example, the reverse voltage of the semiconductor device is 1 at least 40 V, at least 100 V, at least 300 V, at least 600 V or at least 900 V or even more than 900 V.

A configuration of the insulator 142 can be chosen as a function of the blocking voltage, which, as stated above, by the total extension of the semiconductor drift zone 122 and the drift zone doping concentration is defined. For example, the insulation voltage of the insulator 142 by means of a thickness T of the insulator 142 and / or by means of the material of the insulator 142 be set. Examples regarding the thickness T and the material of the insulator 142 will be explained in more detail below.

In one embodiment, the isolator is configured to isolate a voltage that is greater than 50% of the reverse voltage, eg, to isolate a voltage that is at least 75% of the reverse voltage, or a voltage that is at least 100% of the reverse voltage. If the semiconductor device 1 has a blocking voltage of 500 V, consequently, the gate control signal of the control electrode 141 be supplied in an example with a voltage which is also 500 volts. Since the insulator 142 is designed to isolate such voltage, no damage occurs to the semiconductor device 1 on.

The insulator 142 may be designed to withstand an electric field strength greater than 1 MV / cm, such as greater than 2 or 3 MV / cm. Furthermore, the insulator can 142 through the semiconductor drift zone 122 of the semiconductor device 1 extend, for example, even in the region of the second semiconductor contact zone 123 ,

The control electrode 141 which is a gate electrode of the semiconductor device 1 can be, has a proximal end 141-1 and a distal end 141-2 on. The control electrode 141 can, as in 1 and 2 illustrated along the extension direction Y from the proximal end 141-1 to the distal end 141-2 extend. Analogously, the insulator 142 a proximal end 142-1 and a distal end 142-2 and may extend along the extension direction Y from its proximal end 142-1 to its distal end 142-2 extend. Furthermore, the total extension of the insulator 142 along the extension direction Y, ie the distance between the proximal end 142-1 and the distal end 142-2 of the insulator 142 , greater than the total extension of the control electrode 141 along the extension direction Y, ie greater than the distance between the proximal end 141-1 and the distal end 141-2 the control electrode 141 , be.

For example, the total length of the control electrode 141 passing through the proximal end 141-1 and the distal end 141-2 is defined, at least 75% of the total extension of the semiconductor drift zone 122 be. In one embodiment, the length of the control electrode 141 even larger than the total extension of the semiconductor drift zone 122 , Consequently, the control electrode can 141 from the proximal end 141-1 to the distal end 141-2 along the extension direction Y over more than 100% of the total extension of the semiconductor drift zone 122 extend.

For example, a first transition 122-1 between the first semiconductor contact zone 121 and the semiconductor drift zone 122 comparatively deeper in the semiconductor region 12 positioned as the proximal end 141-1 the control electrode 141 , In other words, the first transition can be 122-1 under the proximal end 141-1 the control electrode 141 be arranged. In addition, the distal end may be 141-2 the control electrode 141 comparatively deeper in the semiconductor region 12 be arranged as a second transition 122-2 between the semiconductor drift zone 122 and the second semiconductor contact zone 123 , In other words, the distal end 141-2 below the second transition 122-2 be arranged.

In a further embodiment, the distal end 141-2 above the second transition 122-2 or at the same level as the second transition 122-2 arranged.

The total extension of the semiconductor drift zone 122 can by the distance between the first transition 122-1 and the second transition 122-2 be defined along the extension direction Y. In one embodiment, the control electrode is 141 positioned so that the distance between the first transition 122-1 and the distal end 141-2 the control electrode 141 along the direction of extent at least 75% of the total extension of the semiconductor drift zone 122 is, for example, at least 90%, 100% or more than 100% of the total extension. Furthermore, the control electrode 141 be positioned so that the distance between the proximal end 141-1 the control electrode 141 and the second transition 122-2 along the direction of extent at least 75% of the total extension of the semiconductor drift zone 122 is, for example, at least 90%, 100% or more than 100% of the total extension. In other words, those in the ditch 14 included control electrode 141 at least 75% or at least 90% or even 100% of the total extension of the semiconductor drift zone 122 cover along the extension direction Y.

The semiconductor device 1 For example, a unipolar semiconductor device may be used 1 , such as a MOSFET.

In one embodiment, the control electrode is 141 designed to receive the gate control signal. Such a gate control signal may be provided, for example, by a gate driver (in 1 to 4 not shown) operable with the gate electrode 141 is coupled. Furthermore, the control electrode 141 , in response to the gate control signal, for simultaneously inducing both an inversion channel within the first semiconductor contact zone 121 as well as an accumulation channel within the semiconductor drift zone 122 be designed. For example, the induced inversion channel and the induced accumulation channel form a load current channel that is the first semiconductor contact zone 121 and the second semiconductor contact zone 123 at least partially interconnected. This allows the semiconductor region 12 a load current from the first load contact 11 to the second load contact 13 conduct.

The semiconductor device 1 is designed, for example, to conduct a load current in the range of up to 1 A, up to 10 A, up to 30 A or even higher than 30 A. Furthermore, the trained Load current channel, the first semiconductor contact zone 121 with the second semiconductor contact zone 123 connect electrically.

The control electrode 141 can be compared to the first load contact 12 and the second load contact 13 be isolated, for example by means of the insulator 142 , In such an embodiment, there is neither a first electrical connection between the control electrode 141 and the first load contact 11 another electrical connection between the control electrode 141 and the second load contact 13 ,

The insulator 142 may have a thickness T in a direction perpendicular to the extending direction Y.

For example, the thickness T of the insulator 142 selected as a function of at least one of the following: an electric field strength of the insulator 142 to be able to withstand; a maximum voltage difference between the control electrode 141 and the first semiconductor contact zone 121 ; a maximum voltage difference between the control electrode 141 and the second semiconductor contact zone 123 ; a volume or doping concentration of the second semiconductor contact zone 123 ; a local position of the semiconductor drift zone 122 with respect to the control electrode 141 , Since the voltages of the first semiconductor contact zone 121 , the second semiconductor contact zone 122 and the voltage in the semiconductor drift zone 122 along the extension direction Y, the thickness of the insulator 142 vary according to the maximum of the voltage differences or, alternatively, along the extension direction Y.

As an example, that in 1 is illustrated schematically, the insulator 142 be homogeneous and have a substantially constant thickness T along the extension direction Y, for example, a substantially constant thickness T of at least 1 micron. A method of manufacturing such an insulator 142 may include generating a thermally grown oxide and / or a deposited oxide on the inner sidewalls of the trench 14 include.

In a further embodiment of the semiconductor device 1 a portion of a vertical cross section thereof is in 2 schematically and exemplified, the thickness T along the extension direction Y can increase. In other words, a first thickness T1 of the insulator 142 in an upper part of the trench 14 comparatively smaller than a second thickness T2 in a lower part of the trench 14 be. The insulator 142 For example, it is designed to have its largest thickness in an area where the greatest voltage differences are expected. The variation of the thickness T may occur gradually as in 2 illustrated, or stepped. For example, the second thickness T2 is in the range of 1.1 times to 2.0 times the first thickness T1. Consequently, the thickness of the insulator 142 along the spanwise direction Y vary by a factor ranging from about 1.1 to about 2.0 as compared to a minimum thickness.

A method of making the insulator 142 so that the insulator 142 has a thickness T increasing along the extension direction Y may be provided with a thermally grown oxide on inner sidewalls of the trench 14 kick off. Then, the surface of the oxide can be nitrided, for example by means of low-pressure chemical vapor deposition (LPCVD) and / or by means of a furnace process. A depletion of nitration across the depths of the trench 14 can for example also be implemented. A thermal oxidation step can be performed subsequently. Reaction components, such as O ₂ and / or H ₂ O, may in principle be homogeneous along the depth of the trench 14 be distributed. On the other hand, in the upper part of the trench 14 a dielectric, such as silicon nitride (Si ₃ N ₄ ), are oxidized, whereas in the lower part of the trench 14 Silicon can be oxidized, which can occur faster than compared to the oxidation of silicon nitride. Consequently, the resulting thickness of the nitride may be inhomogeneous. Such a method allows a wedge-shaped insulator within a thermal oxidation step 142 to produce, for example, at least partially made of silicon dioxide. The largest thickness T of the insulator 142 for example, within the lower part of the trench 14 in an area where the highest voltage differences can be expected.

Furthermore, the insulator 142 have a thickness along the extending direction Y corresponding to the thickness T in the direction perpendicular to the extending direction Y. For example, the distance along the extension direction Y may be between the proximal end 141-1 the control electrode 141 and the proximal end 142-1 of the insulator 142 substantially identical to the thickness T in the direction perpendicular to the extension direction Y, that in the upper part of the trench 14 is available. Further, the distance along the extension direction Y between the distal end 141-2 the control electrode 141 and the distal end 142-2 of the insulator 142 substantially identical to the thickness T in the direction perpendicular to the extension direction Y, that in the lower part of the trench 14 is available.

In one embodiment, the insulator is 142 implemented at least in part as a topological insulator. The insulator 142 includes for example a topological insulator or is such. The insulator 142 can thus allow flow of a stream that is substantially free of energy losses, at least in an area close to the surface of the trench 14 ,

The insulator 142 may include any material suitable for insulating a voltage that is at least 50% of the reverse voltage. The insulator 142 includes, for example, silicon dioxide and / or silicon nitride and / or silicon oxynitride and / or hafnium oxide.

The semiconductor contact zones 121 and 123 may also be doped. For example, the semiconductor contact zone 121 doped with second dopants of a second conductivity type that is complementary to the first conductivity type. Furthermore, the doping concentration may be within the first semiconductor contact zone 121 at least ten times higher than the drift zone doping concentration. Similarly, the second semiconductor contact zone 123 be doped with third dopants of either the first or the second conductivity type. Furthermore, the doping concentration within the semiconductor contact zones 123 at least ten times higher than the drift zone doping concentrations. Further, optional aspects of the semiconductor contact zones 121 and 123 in more detail with reference to 3A and 4 explained.

3A schematically illustrates a portion of a vertical section through a semiconductor device 1 according to one or more embodiments and 3B schematically illustrates a portion of a horizontal section along a plane AA of the semiconductor device 1 from 3A ,

The basic structure of by 3A and 3B illustrated semiconductor device 1 basically corresponds to the structure of in 1 illustrated semiconductor device 1 that was described above. The semiconductor device 1 can a variety of trenches 14 include, which may be arranged periodically, such as at a substantially constant distance between two adjacent trenches 14 , which is referred to below as P division. In one embodiment, the pitch P, ie, the distance between two adjacent trenches 14 in the range of a few microns. The pitch P is, for example, in the range of 1 μm to 10 μm, such as in the range of 3 μm to 7 μm.

The following is an example of a specific configuration of the in 3A illustrated semiconductor device 1 be presented in more detail:
For example, a minimum value of the pitch P may be determined by, first, the thickness T of the insulator 142 and consequently by the maximum possible electric field strength in the insulator 142 and second, a maximum reverse voltage between the control electrode 141 and an adjacent semiconductor region, such as one or more semiconductor regions 121 . 122 and 123 to be limited.

The pitch P may be around the semiconductor contact zones due to a width of a corresponding area needed 121 and 123 and the control electrode 141 to be increased. The widths may be parallel to the thickness T. For example, the widths may each be in the range between about 50 nm and about 3 μm. For example, each width may be about 500 nm. In one embodiment, the pitch P may be linear with the reverse voltage between the control electrode 141 and the first semiconductor contact zone 121 and dimensions of a region used to contact the first semiconductor contact zone 121 needed, and an area needed to create the control electrode 141 within the trench 14 is needed, scale. For example, if the reverse voltage between the control electrode 141 and the first semiconductor contact zone 121 is about 600V and if the maximum electric field strength in the insulator 142 is about 3 MV / cm, the thickness of the insulator can be 124 be about 2 microns. If the widths of the control electrode 141 and the first semiconductor contact zone 121 Furthermore, the pitch P may be in the range of several μm, such as 5 μm.

In addition, the total extension of the semiconductor drift zone 122 along the direction Y with the required reverse voltage of the semiconductor device 1 scale, for example, with the required reverse voltage between the first semiconductor contact zone 121 and the second semiconductor contact zone 123 , For example, if the semiconductor drift zone 122 is substantially made of silicon, an extension along the extending direction Y of about 8 μm to 10 μm per 100 V may be appropriate.

In one embodiment, the total extension of the semiconductor drift zone 122 along the extension direction Y amount to some 10 microns. For example, to achieve a blocking voltage of about 600 V, the total extension of the semiconductor drift zone 122 be about 55 microns, for example, if silicon as a material for the semiconductor drift zone 122 is used.

According to a further embodiment, the semiconductor drift zone comprises 122 a material with a broad band gap, eg SiC. The semiconductor drift zone 122 For example, it mainly comprises SiC or consists essentially of SiC. These Embodiment involves the following approach: For materials with a broad bandgap, eg, SiC, the overall extension of the semiconductor drift zone 122 along the extension direction Y comparatively significantly smaller than silicon, for example by a factor of approximately 10 at a given reverse voltage of the semiconductor device 1 , As the thickness T of the insulator 142 may be independent of the material of the semiconductor drift zone, use of a wide bandgap material, eg SiC, may be used to create the semiconductor drift zone 122 to a significant reduction in the depth of the trench 14 lead, ie to a significant reduction in the total extension of the trench 14 along the extension direction Y. Such a reduced depth of the trench 14 may be the manufacture of the semiconductor device 1 facilitate. For example, a voltage may be in the semiconductor device 1 , For example, a mechanical stress due to temperature changes of the semiconductor device 1 due to the reduced volume of the insulator 142 within the trench 14 , be reduced.

The first load contact 11 may be a source contact (S) and the second load contact 13 may be a drain contact (D). The ones in the trenches 14 contained control electrodes 141 may gate electrodes (G) for controlling the semiconductor device 1 be. Consequently, the semiconductor device 1 be a vertical MOSFET.

As in 3A illustrates, the semiconductor device 1 a plurality of separate first semiconductor contact zones 121 include. Each of the first semiconductor contact zones 121 may be a first semiconductor body region 121-1 which are in contact with the semiconductor drift zone 122 is. Furthermore, each of the first semiconductor contact zones 121 a first semiconductor contact region 121-2 which are in contact with both the first load contact 11 as well as the first semiconductor body region 121-1 is.

Every first semiconductor body region 121-1 is doped, for example, with second dopants of the second conductivity type that is complementary to the first conductivity type, eg, each first semiconductor body region 121-1 may be a p-doped region.

Each first semiconductor contact region 121-2 may be doped with third dopants of the first conductivity type. Each of the first semiconductor contact regions 121-2 is an n ⁺ -doped semiconductor region. To create an electrical contact between the first load contact 11 and the first semiconductor contact regions 121-2 can first contact elements 11-1 within each first semiconductor contact zone 121 be arranged. The first dopants are identical to the third dopants, for example.

The first load contact 11 For example, a metal layer of the semiconductor device 1 include. The first load contact 11 may comprise at least one of the following materials: aluminum (Al), copper (Cu), nickel (Ni), silver (Ag), gold (Au), platinum (Pt) and / or titanium (Ti). The first load contact 11 may further include a diffusion barrier layer (not shown), for example at a lower part of the first load contact 11 that is to the semiconductor region 12 pointing. The diffusion barrier layer may comprise an electrically conductive nitride, such as tantalum nitride (TaN), titanium nitride (TiN). Furthermore, between the first load contact 11 and the semiconductor region 12 a contact plug (not shown), wherein such a contact plug may comprise silicon (Si) and / or tungsten (W). In addition, the semiconductor region 12 an upper contact layer (not shown) formed in an upper surface region of the semiconductor region 12 and near the first load contact 11 is arranged. The top contact layer may also include an electrically conductive nitride and / or silicide, such as a titanium silicide, a tantalum silicide and / or a cobalt silicide.

The second load contact 13 and a transition between the second load contact 13 and the semiconductor region 12 can be on one of the above with respect to the first load contact 11 explained in a similar way. Accordingly, the second load contact 13 also include a metal layer. The second load contact 13 may comprise at least one of the following materials: aluminum (Al), copper (Cu), nickel (Ni), silver (Ag), gold (Au), platinum (Pt) and / or titanium (Ti). In addition, the second load contact 13 another diffusion barrier layer (not shown), for example, at an upper part of the second load contact 13 that is to the semiconductor region 12 pointing. The further diffusion barrier layer may comprise an electrically conductive nitride, such as tantalum nitride (TaN), titanium nitride (TiN). Further, between the second load contact 11 and the semiconductor region 12 a contact plug (not shown), wherein such another contact plug may comprise silicon (Si) and / or tungsten (W). In addition, the semiconductor region 12 comprise a lower contact layer (not shown) attached to a lower region of the semiconductor region 12 and near the second load contact 13 is arranged. The lower contact layer may also include an electrically conductive nitride and / or silicide, such as a titanium silicide, a tantalum silicide and / or a cobalt silicide.

The first contact elements 11-1 may be part of the first semiconductor contact zones 121 be. Furthermore, the first contact elements 11-1 comprise a semiconductor material. The first contact elements 11-1 are, for example, with the same dopants as in the first semiconductor body regions 121-1 may be present, doped, with a doping concentration in the first contact elements 11-1 comparatively higher than a doping concentration in the first semiconductor body regions 121-1 can be.

The second semiconductor contact zone 123 can be comparatively highly doped. The second semiconductor contact zone 123 is, for example, compared with the same dopants as in the first semiconductor contact region 121-2 doped. The second semiconductor contact zone 123 is, for example, an n ⁺ drain contact zone.

As in 3B Illustrated may be any control electrode 141 from the first semiconductor contact region 121-2 and from the first contact element 11-1 by means of the insulator 142 be isolated.

Furthermore, anyone can ditch 14 have a substantially rectangular or square cross section, as in 3B is illustrated in a horizontal cross-section. In a further embodiment, each trench 14 in a horizontal cross section have a substantially circular or elliptical cross-section (not shown). In yet another embodiment, each trench 14 in a horizontal cross-section have a substantially rectangular or square cross-section with rounded corners (not shown).

Both the insulator 142 as well as the control electrode 141 may have a substantially rectangular cross-section, such as a substantially square cross section, a substantially square cross section with rounded corners or a substantially circular or elliptical cross section. In one embodiment, the insulator 142 a substantially square cross section with a few microns edge width. In the example of the specific configuration described above, the edge width may be about 4.5 μm.

4 schematically illustrates a portion of a vertical section through another semiconductor device 1 according to one or more embodiments. The basic structure of the semiconductor device 1 from 4 basically corresponds to the structure of in 1 illustrated semiconductor device 1 , In this respect, reference is made to the above.

The semiconductor device 1 from 4 can have a basically symmetrical vertical structure. For example, the semiconductor device 1 according to 4 the following features: Each of the first semiconductor contact zones 121 includes the first semiconductor body region 121-1 in contact with the semiconductor drift zone 122 is, and the first semiconductor contact region 121-2 in contact with the first load contact 11 is. Analogously, the semiconductor component comprises 1 according to 4 a plurality of second semiconductor contact zones 123 wherein each of the second semiconductor contact zones 123 a second semiconductor body region 123-1 which is in contact with the semiconductor drift zone 122 is, and a second semiconductor contact region 123-2 in contact with the second load contact 13 is. Furthermore, each of the first semiconductor body regions 121-1 and the second semiconductor body regions 123-1 be doped with second dopants of the second conductivity type complementary to the first conductivity type. In addition, each of the first semiconductor contact regions 121-2 and the second semiconductor contact regions 123-2 be doped with third dopants of the first conductivity type. This allows the semiconductor device 1 be designed to bi-directionally lock the reverse voltage and to conduct a load current bidirectionally, ie from the first load contact 11 to the second load contact 13 and vice versa, from the second load contact 13 to the first load contact 11 , Consequently, the first load contact 11 a first source contact (S1) and the second load contact 13 may be a second source contact (S2).

To create an electrical contact between the second load contact 13 and the second semiconductor contact regions 123-2 can be second contact elements 13-1 within each second semiconductor contact zone 123 be arranged.

The second contact elements 13-1 may be similar to that in comparison with the first contact elements presented above 11-1 be implemented. Accordingly, the second contact elements 13-1 Part of the second semiconductor contact zones 123 be. Furthermore, the second contact elements 13-1 comprise a semiconductor material. The second contact elements 13-1 are, for example, with the same dopants as they are in the second semiconductor body regions 123-1 may be doped, with a doping concentration in the second contact elements 13-1 comparatively higher than a doping concentration in the second semiconductor body regions 123-1 can be. Consequently, the second contact elements 13-1 be heavily p-doped semiconductor regions.

For example, the second semiconductor contact regions 123-2 n ⁺ -doped semiconductor regions. Furthermore, the second semiconductor body regions 123-1 be p-type semiconductor regions.

5A schematically illustrates a circuit diagram of a circuit arrangement according to one or more embodiments. The circuit arrangement 2 includes a power supply 21 to supply a load 22 with power, being the power supply 21 a first power output 211 and a second power output 212 having. The power supply 21 is designed to provide an output voltage greater than 40 V between the first power output 211 and the second power output 212 , The power supply 21 For example, a battery that provides a DC voltage.

The circuit arrangement 2 further includes a load current path 23 wherein the load current path is for coupling the load 22 with the first power output 211 and the second power output 212 is designed. Although the load 22 As a simple ohmic resistance is illustrated, it is understood that the load 22 may also be a load network or other circuit configuration that consumes electrical energy. A load current path 23 For example, cables, connectors, and / or other transmission means may be used to transport the power supply 21 provided power to the load 22 include.

Within the load current path 23 is a semiconductor device 1 included, that has a control terminal 17 , a first load connection 18 and a second load terminal 19 includes. The semiconductor device 1 the circuit arrangement 2 has, for example, one such as in one of 1 to 4 illustrated construction on.

Accordingly, the first load port 18 in electrical contact with the first load contact 11 of the semiconductor device 1 be, the second load connection 19 can be in contact with the second load contact 13 be and the control electrode (s) 141 can (can) be in electrical contact with the control terminal 17 of the semiconductor device 1 be. Consequently, a load current flowing through the load current path 23 flows through the first load port 18 , the first contact 11 , the semiconductor region 12 including the first semiconductor contact zone (s) 121 , the semiconductor drift zone 122 and the second semiconductor contact zone (s) 123 , the second load contact 13 and the second load terminal 19 of the semiconductor device 1 go through when the semiconductor device 1 is operated in a on state. In other words, the semiconductor device 1 by means of the first load connection 18 and the second load terminal 19 with the load 22 be connected in series.

The semiconductor device 1 the circuit arrangement 2 may be an n-channel semiconductor device 1 be. As explained above, the gate control electrode (s) may (may) 141 of the semiconductor device 1 , in response to the control signal, for simultaneously inducing both an inversion channel within the first semiconductor contact zone 121 as well as an accumulation channel within the semiconductor drift zone 122 be designed, wherein the semiconductor drift zone 122 can be n-doped. For example, the induced inversion channel and the induced accumulation channel form a load current channel that is the first semiconductor contact zone 121 and the second semiconductor contact zone 123 connects with each other.

The circuit arrangement 2 further comprises a control current path 26 , wherein the control current path 26 the power supply 21 to the control terminal 17 coupled. Furthermore, the control current path includes 26 a controllable switch 24 which is adapted to receive a switch control signal 24-1 and, in response to the switch control signal 24-1 , for electrically connecting the control terminal 17 with either the first power output 211 or the second power output 212 ,

For example, when the switch control signal 24-1 is provided such that the control terminal 17 of the semiconductor device 1 electrically with the first power output 211 connected is. Consequently, this can be done at the first power output 211 existing electrical potential to the control terminal 17 and thereby the control electrode (s) 141 , For example, if at the first power port 211 existing electrical potential is the high potential, such a state of the controllable switch 24 the semiconductor device 1 causing it to turn on, causing a flow of a load current through the load current path 23 outside the semiconductor device 1 and the load current channel within the semiconductor device 1 is possible. In such a configuration, this may be at the first power port 211 existing electrical potential of both the load 22 as well as the control terminal 17 of the semiconductor device 1 be supplied. This potential may be more than 40V, such as 100V, 300V, 600V or even more than 600V. It should also be noted that the second power output 212 may be electrically connected to ground (not shown).

Providing the switch control signal 24-1 such that the control terminal 17 electrically with the second power output 212 is connected, the semiconductor device 1 cause it to turn off, causing the flow of a load current through the load current path 23 outside the semiconductor device 1 and through the load current channel within the semiconductor device 1 is locked, ie, that the load 22 electrically from the power supply 21 is disconnected. If the semiconductor device 1 As a p-channel semiconductor device is implemented, a complementary to the above-explained principle control method for controlling such a p-channel semiconductor device can be applied.

According to one embodiment, the power supply is used 21 not only for supplying with electric power for the load 22 but also serves as a gate driver for directly driving the control electrode (s) 141 of the semiconductor device 1 , In other words, the semiconductor device 1 directly by means of the power supply 21 to be controlled. Another gate driver unit in addition to the controllable switch 24 may be obsolete.

According to another in 5B schematically and exemplified embodiment, the circuit arrangement 2 also a charge pump 27 include. The charge pump 27 can the power supply 21 downstream and the controllable switch 24 be arranged upstream. Furthermore, the charge pump 27 at least partially within the control current path 26 be included. The charge pump 27 For example, it is designed to receive the output voltage from the power supply 21 is provided, and, depending on the output voltage of the power supply 21 for generating a charge pump output voltage, wherein the charge pump output voltage is comparatively larger than the output voltage of the power supply 21 can be. The controllable switch 24 can the charge pump 27 can be arranged downstream and can be designed to receive the charge pump output voltage. The controllable switch 24 For example, it is designed to electrically connect the control terminal 17 with either a first output port 27-1 the charge pump 27 or a second output port 27-2 the charge pump 27 in response to the switch control signal 24-1 , wherein the first output terminal 27-1 with the first power output 211 is connected and wherein the second output terminal 27-1 with the second power output 212 connected is.

The charge pump 27 includes, for example, an input capacitor 271 and an output capacitor 272 , The output capacitor 272 may be configured to supply the charge pump output voltage to the controllable switch 24 , Furthermore, the charge pump 27 a first diode 273 and a second diode 274 and a switch arrangement 275 include, wherein these components of the charge pump 27 with each other as in 5B can be connected. Both the first diode 273 as well as the second diode 274 can be in the control stream path 26 be included. The switch arrangement 275 may be configured to electrically connect an electrode of the input capacitor 271 with either the first power output 211 or the second power output 212 in response to a control signal, that of the switch assembly 275 is supplied. Another electrode of the input capacitor 271 can with a cathode terminal of the first diode 273 and an anode terminal of the second diode 274 be connected. An anode terminal of the first diode 273 can with the first power output 211 be connected. A cathode terminal of the second diode 274 can with an electrode of the output capacitor 272 be connected, the electrical potential of the first output terminal 27-1 can provide. The other electrode of the output capacitor 272 can the electric potential of the second output terminal 27-2 can provide and can with the second power output 212 be connected. This allows the charge pump 27 be designed to generate the charge pump output voltage that is greater than the output voltage from the power supply 21 is provided, such as about twice as large as that of the power supply 21 provided output voltage. The charge pump output voltage can be the control terminal 17 by means of the controllable switch 24 are supplied as the gate control signal.

For example, if the semiconductor device 1 is rarely switched, the semiconductor device 1 through the charge pump 27 be controlled, since the average current for charging the gate electrode (s) 141 can be comparatively small.

The charge pump 27 may be configured to provide its charge pump output voltage as the gate control signal, for example by providing the charge pump output voltage between the control terminal 17 and the first load terminal 18 or the second load port 19 , The charge pump output voltage may be that of the power supply 21 exceed provided output voltage. As a resistor of the semiconductor device 1 in an on-state may depend on the voltage between the control electrode 141 and the first semiconductor contact zone 121 or the second semiconductor contact zone 123 and the semiconductor drift zone 122 is applied, an increased voltage of the gate control signal may lead to a reduced on-state resistance. As explained above, the blocking capability of the insulator 142 be designed to the maximum blocking capability of the semiconductor device 1 between the first semiconductor contact zone 121 and the second semiconductor contact zone 123 to match, ie to the reverse voltage of the semiconductor device 1 , However, the semiconductor device could 1 be designed such that this blocking capability between the first semiconductor contact zone 121 and the second semiconductor contact zone 123 the from the power supply 21 For example, to allow some reserve in the case of voltage transients, for example, during the switching off of the load current through the load 22 may occur. Consequently, the charge pump 27 be used to generate the gate control signal with a voltage equal to that of the power supply 21 provided output voltage exceeds.

The controllable switch 24 can be realized by means of a semiconductor switch arrangement or by means of mechanical switches.

Weight 22 can either be between the first power output 211 and the second load terminal 19 (as in 5A and 5B illustrated) or alternatively or additionally between the second power output 212 and the first load connection 18 be switched.

Furthermore, it is understood that the control current path 26 may have an ohmic resistance, such as a gate resistance. Furthermore, the control current path 26 a further diode (not shown), eg another diode arranged such that the further diode avoids consumption of charge which is present in the control electrode (s) 141 is included, for example, in the event that the voltage of the power supply 21 suddenly falls off. The further diode may further comprise, for example, a cathode terminal and an anode terminal, wherein the cathode terminal is electrically connected to the control terminal 17 is connected and the anode terminal to the first power output 211 or corresponding to the first output terminal 27-1 is connected, if the circuit arrangement 2 the charge pump 27 includes.

6 schematically illustrates a circuit diagram of a circuit arrangement 2 according to one or more embodiments. Basically, the structure corresponds to the in 6 illustrated circuitry 2 the structure of in 5A illustrated circuitry 2 , According to the in 6 illustrated embodiment is the power supply 21 an alternating current power supply that supplies an alternating voltage between the first power output 211 and the second power output 212 provides. In such a case, the circuit arrangement 2 in addition a rectifier circuit 25 include, such as a diode bridge. The rectifier circuit 25 includes for example as in 6 illustrates four diodes 251 . 252 . 253 and 254 , Furthermore, the rectifier circuit 25 a buffer capacitor 255 comprising a DC voltage corresponding to the rectified AC voltage. The DC voltage of the buffer capacitor 255 can by means of DC connections 255-1 and 255-2 be provided.

The control connection 17 of the semiconductor device 1 is by means of the control current path 26 , which is the controllable switch 24 and a series resistor 171 , which may be a gate resistor, may be connected to the DC terminals 255-1 and 255-2 coupled.

Regarding the operation of in 6 illustrated circuitry 2 is on the re 5A and 5B referenced statements. The semiconductor device 1 is done by supplying the switch control signal 24-1 so that the control terminal 17 (about the series resistance 171 ) electrically connected to the DC connection 255-1 is connected, turned on. Furthermore, the semiconductor device 1 by supplying the switch control signal 24-1 so that the control terminal 17 (about the series resistance 171 ) electrically to the other DC terminal 255-2 is connected to be turned off.

Furthermore, it is understood that the circuit arrangement 2 according to 6 also a charge pump 27 may contain. The charge pump 27 for example, the buffer capacitor 255 downstream and the controllable switch 24 be arranged upstream.

The semiconductor device 1 can, as in one or more of 1 to 6 is schematically illustrated, by supplying the gate control signal with a voltage which is at least 50% of the blocking voltage of the semiconductor device 1 is, to the control electrode (s) 141 operate. Like for example the in 5A . 5B and 6 can be derived, the semiconductor device 1 Not only designed to lock a voltage that is more than 100% of that of the power supply 21 is also provided with a gate control signal (provided by the control terminal 17 ), which has a voltage which is also at least 100% of the output voltage of the power supply 21 is. Consequently, the insulator can 142 be designed to withstand such a voltage.

As explained above, the semiconductor device 1 in accordance with one or more embodiments, by supplying the gate control signal with a voltage that is at least 50% of the reverse voltage to the control electrode 141 be turned on. For changing the state of the semiconductor device 1 For example, from an off state to an on state, or vice versa, the voltage of the gate control signal may be at least 40V, for example.

The embodiments described above include the approach that a load should sometimes be connected to a power supply and sometimes disconnected from the power supply shall be. Occasionally, the rate of connecting the load to the power supply and disconnecting the load from the power supply may be very low, such as once an hour, once a day, or even only once during the entire life of the load. So-called main switches or master switches are used to accomplish such low rate connection / disconnection functionality. In the event of a failure, such as a power failure or a battery fault, or a loss of ground connection, it may be desirable to disconnect the load from the power supply. Mechanical switches may be used, for example, to accomplish such connection / disconnection functionality.

However, such mechanical switches may have a comparatively large switching delay time which, in the event of a fault, may result in damage to the power supply and / or the load. If a mechanical switch is switched frequently, i. however, frequently used to connect and disconnect the load from / to the power supply, the wear of the mechanical switch can cause damage or even result in a loss of functionality of the switch.

According to one or more embodiments, it is proposed to use a semiconductor device instead of a mechanical switch to fulfill the connection / disconnection functionality, eg, one as in one of 1 to 6 schematically illustrated semiconductor device. Such a semiconductor device may have a comparatively low on-state resistance and thus may be suitable for continuously conducting a load current over a comparatively long period of time with only small losses. For example, the on-state resistance may be reduced by providing the comparatively high voltage gate control signal, which, as stated above, may be within the reverse bias voltage of the semiconductor device, eg, at least 50% of the reverse voltage, at least 75% of the reverse voltage or even higher, such as at least 100% of the reverse voltage. Due to the low rate of switching operation of the semiconductor device, the semiconductor device may not necessarily be designed for small switching losses, but rather exclusively for small on-state losses.

Features of further embodiments are defined in the dependent claims. The features of further embodiments and the features of the embodiments described above may be combined to form additional embodiments, as far as the features are not expressly described as being alternative to one another.

For ease of understanding of exemplary embodiments schematically illustrated in the drawings, some of the control electrodes are 141 labeled with a "G", which may be an abbreviation for "gate". The contacts 11 and 13 have occasionally been labeled with an "S", which may be an abbreviation for "Source", or correspondingly with a "D", which may be an abbreviation for "Drain".

As described above, the insulator 142 a dielectric material. The insulator 142 includes, for example, a silicon dioxide and / or silicon nitride and / or silicon oxynitride and / or hafnium oxide. Furthermore, the insulator 142 a so-called high-k dielectric. Also it is possible that the insulator 142 Mixtures or alloys of such materials and / or a plurality of layers of different dielectric materials.

Regarding the gate electrode (s) 141 It should be noted that the gate electrode may comprise polycrystalline silicon, metal silicides, metals and / or electrically conductive ceramics and / or mixtures or alloys of such materials and / or a plurality of layers of different electrically conductive materials.

As described above, the semiconductor region may mainly consist of a semiconductor drift zone 122 , eg, an n ^- drift region, exist in the semiconductor junctions, such as pn junctions, from a corresponding junction between the first semiconductor contact zone 121 and the semiconductor drift zone 122 and / or a corresponding transition between the second semiconductor contact zone 123 and the semiconductor drift zone 122 can be formed.

Further, the term "doping concentration" in this specification may refer to a total doping concentration or corresponding to an average doping concentration or to a surface charge carrier density of a specific semiconductor region. Thus, e.g. That is, a statement that one specific semiconductor region has a certain doping concentration that is comparatively higher or lower than a doping concentration of another semiconductor region indicates that the respective average doping concentrations of the semiconductor regions are different from each other.

The in the semiconductor drift region 122 For example, existing drift zone doping concentration may have an average doping concentration with respect to the total volume of the semiconductor drift region 122 be. Furthermore, those in the semiconductor contact zones 121 and 123 existing doping concentrations, such as in the first and second semiconductor contact regions 121-1 and 123-1 , be corresponding average doping concentrations with respect to the respective total volume of the first or the second semiconductor contact region.

In the above, embodiments concerning semiconductor devices, embodiments concerning circuit arrangements including a semiconductor device, and embodiments concerning methods of controlling semiconductor devices have been explained. These semiconductor devices are based, for example, on silicon (Si). Accordingly, a monocrystalline semiconductor region or layer, eg, the semiconductor regions 121 . 122 . 123 of exemplary embodiments, typically a monocrystalline Si region or an Si layer. In other embodiments, polycrystalline or amorphous silicon may be employed.

It is understood, however, that the semiconductor zones 121 . 122 . 123 may be made of any semiconductor material that is suitable for producing a semiconductor device. Examples of such materials include, but are not limited to, elemental semiconductor materials such as silicon (Si) or germanium (Ge), group IV compound semiconductor materials such as silicon carbide (SiC) or silicon germanium (SiGe), binary, ternary or quaternary III-V Semiconductor materials such as gallium nitride (GaN), gallium arsenide (GaAs), gallium phosphide (GaP), indium phosphide (InP), indium gallium phosphide (InGaPa), aluminum gallium nitride (AlGaN), aluminum indium nitride (AlInN), indium gallium nitride (InGaN), aluminum gallium indium nitride (AlGaInN) or indium gallium arsenide phosphide ( InGaAsP), and binary or ternary II-VI semiconductor materials, such as cadmium telluride (CdTe) and mercury cadmium telluride (HgCdTe), to name but a few. The aforementioned semiconductor materials are also referred to as "homojunction semiconductor materials". When two different semiconductor materials are combined, a heterojunction semiconductor material is formed. Examples of heterojunction semiconductor materials include aluminum gallium nitride (AlGaN) aluminum gallium indium nitride (AlGaInN), indium gallium nitride (InGaN) aluminum gallium indium nitride (AlGaInN), indium gallium nitride (InGaN) gallium nitride (GaN), aluminum gallium nitride (AlGaN) gallium nitride (GaN), indium gallium nitride ( InGaN) aluminum gallium nitride (AlGaN), silicon silicon carbide (SixC1-x) and silicon-SiGe heterojunction semiconductor materials. For semiconductor device applications, currently mainly Si, SiC, GaAs and GaN materials are used.

Spatial terms, such as "below," "below," "lower," "above," "upper," and the like, are used for ease of description to describe the position of one element relative to a second element. It is intended that these terms include various orientations of the device in addition to those depicted in the figures. Further, terms such as "first," "second," and the like are also used to describe various elements, regions, sections, and so on, and again, they are not intended to be limiting. Throughout the description, like terms refer to similar elements.

The terms "comprising," "including," "including," "comprising," "pointing," and the like are open-ended and indicate the presence of the specified elements or features, but exclude any additional elements or features. It is intended that the articles "a", "an" and "the" include both the plural and the singular, unless the context clearly indicates otherwise.

In view of the above range of variations and applications, it should be understood that the present invention is not limited by the foregoing description, nor is it limited by the accompanying drawings. Instead, the present invention is limited only by the following claims and their legal equivalents.

Claims (20)

Semiconductor device ( 1 ), wherein the semiconductor device ( 1 ) a first load contact ( 11 ), a second load contact ( 13 ) and a semiconductor region ( 12 ) between the first load contact ( 11 ) and the second load contact ( 13 ), wherein the semiconductor region ( 12 ) Includes: a first semiconductor contact zone ( 121 ), wherein the first semiconductor contact zone ( 121 ) in contact with the first load contact ( 11 ); A second semiconductor contact zone ( 123 ), wherein the second semiconductor contact zone ( 123 ) in contact with the second load contact ( 13 ); A semiconductor drift zone ( 122 ), wherein the semiconductor drift zone ( 122 ) between the first semiconductor contact zone ( 121 ) and the second semiconductor contact zone ( 123 ) and is doped with first dopants of a first conductivity type, wherein the semiconductor drift zone ( 122 ) the first semiconductor contact zone ( 121 ) to the second semiconductor contact zone ( 123 ), wherein the semiconductor device ( 1 ) further comprises: - a ditch ( 14 ) extending along an extension direction (Y) from the first semiconductor contact zone (Y). 121 ) to the second semiconductor contact zone ( 123 ), into the semiconductor region ( 12 ), wherein the trench ( 14 ) a control electrode ( 141 ) and an isolator ( 142 ), wherein the insulator ( 142 ) the control electrode ( 141 ) from the semiconductor region ( 12 ), and wherein - the control electrode ( 141 ) within the trench ( 14 ) along the extension direction (Y) at least as far as 75% of the total extent of the semiconductor drift zone ( 122 ) extends in the extension direction (Y); The semiconductor drift zone ( 122 ) has a drift zone doping concentration of first dopants, the drift zone doping concentration and the total extension of the semiconductor drift zone ( 122 ) a reverse voltage of the semiconductor device ( 1 ), - the insulator ( 142 ) is designed to insulate a voltage that is at least 50% of the reverse voltage. Semiconductor device ( 1 ) according to claim 1, wherein: - the first semiconductor contact zone ( 121 ) a first semiconductor body region ( 121-1 ) in contact with the semiconductor drift zone ( 122 ), and a first semiconductor contact region ( 121-2 ) in contact with the first load contact ( 11 ); The second semiconductor contact zone ( 123 ) a second semiconductor body region ( 123-1 ) in contact with the semiconductor drift zone ( 122 ), and a second semiconductor contact region ( 123-2 ) in contact with the second load contact ( 13 ); Each of the first semiconductor body region ( 121-1 ) and the second semiconductor body region ( 123-1 ) is doped with second dopants of the second conductivity type complementary to the first conductivity type; Each of the first semiconductor contact region ( 121-2 ) and the second semiconductor contact region ( 123-2 ) is doped with third dopants of the first conductivity type. Semiconductor device ( 1 ) according to claim 1 or claim 2, wherein the control electrode ( 141 ) a proximal end ( 141-1 ) and a distal end ( 141-2 ) and extending from the proximal end ( 141-1 ) to the distal end ( 141-2 ) along the extension direction (Y) over more than 100% of the total extension of the semiconductor drift zone (FIG. 122 ). Semiconductor device ( 1 ) according to one of the preceding claims, wherein the reverse voltage is at least 40 V. Semiconductor device ( 1 ) according to any one of the preceding claims, wherein the insulator ( 142 ) is designed to insulate a voltage that is at least 100% of the reverse voltage. Semiconductor device ( 1 ) according to any one of the preceding claims, wherein the insulator ( 142 ) is implemented at least partially as a topological insulator. Semiconductor device ( 1 ) according to any one of the preceding claims, wherein the insulator ( 142 ) has a thickness (T) of at least 1 μm in a direction perpendicular to the extension direction (Y). Semiconductor device ( 1 ) according to any one of the preceding claims, wherein the insulator ( 142 ) in a direction perpendicular to the extending direction (Y) has a thickness (T) increasing along the extending direction (Y). Semiconductor device ( 1 ) according to one of the preceding claims, wherein the control electrode ( 141 ) from the first load contact ( 12 ) and from the second load contact ( 13 ) is isolated. Semiconductor device ( 1 ) according to one of the preceding claims, wherein the semiconductor component ( 1 ) is a unipolar semiconductor device. Semiconductor device ( 1 ) according to one of the preceding claims, wherein the control electrode ( 141 ) is adapted to receive a gate control signal and simultaneously induce both an inversion channel within the first semiconductor contact zone ( 121 ) as well as an accumulation channel within the semiconductor drift zone ( 122 ) in response to the gate control signal. Semiconductor device ( 1 ) according to claim 11, wherein the induced inversion channel and the induced accumulation channel form a load current channel comprising the first semiconductor contact zone ( 121 ) and the second semiconductor contact zone ( 123 ) at least partially interconnects. Semiconductor device ( 1 ) according to claim 1, wherein the semiconductor contact zone ( 121 ) is doped with second dopants of a second conductivity type that is complementary to the first conductivity type. Semiconductor device ( 1 ) according to claim 13, wherein the doping concentration within the first semiconductor contact zone ( 121 ) is at least ten times as high as the drift zone doping concentration. Semiconductor device ( 1 ) according to claim 1, wherein the second semiconductor contact zone ( 123 ) With third dopants of either the first or the second conductivity type is doped. Semiconductor device ( 1 ) according to claim 15, wherein the doping concentration within the second semiconductor contact zone ( 123 ) is at least ten times as high as the drift zone doping concentration. Circuit arrangement ( 2 ), comprising: - a power supply ( 21 ), whereby the power supply ( 21 ) a first power output ( 211 ) and a second power output ( 212 ) and is designed to provide an output voltage of greater than 40 V between the first power output ( 211 ) and the second power output ( 212 ); A load current path ( 23 ), the load current path ( 23 ) is designed for coupling a load ( 22 ) to the first power output ( 211 ) and to the second power output ( 212 ); A semiconductor device ( 1 ), which in the load current path ( 23 ), wherein the semiconductor device ( 1 ) a control terminal ( 17 ), a first load terminal ( 18 ) and a second load terminal ( 19 ), wherein the semiconductor device ( 1 ) is arranged to by means of the first load terminal ( 18 ) and the second load terminal ( 19 ) with the load ( 22 ) to be connected in series; A control current path ( 26 ), the control current path ( 26 ) the power supply ( 21 ) with the control connection ( 17 ) connects; - a controllable switch ( 24 ) located in the control current path ( 26 ), the controllable switch ( 24 ) is adapted to receive a switch control signal ( 24-1 ) and, in dependence on the switch control signal ( 24-1 ), for electrically connecting the control terminal ( 17 ) with either the first power output ( 211 ) or the second power output ( 212 ). Circuit arrangement ( 2 ) according to claim 17, wherein the circuit arrangement ( 2 ) a charge pump ( 27 ), the power supply ( 21 ) and the controllable switch ( 24 ) is arranged upstream, wherein the charge pump ( 27 ) is designed to receive the output voltage from the power supply ( 21 ) and, depending on the received output voltage, for generating a charge pump output voltage and for supplying the charge pump output voltage to the controllable switch ( 24 ). Circuit arrangement ( 2 ) according to claim 17 or claim 18, wherein the semiconductor device ( 1 ) a first load contact ( 11 ) in electrical contact with the first load terminal ( 18 ), a second load contact ( 13 ) in electrical contact with the second load terminal ( 19 ) and a semiconductor region ( 12 ) between the first load contact ( 11 ) and the second load contact ( 13 ), wherein the semiconductor region ( 12 ) Includes: a first semiconductor contact zone ( 121 ), wherein the first semiconductor contact zone ( 121 ) in contact with the first load contact ( 11 ); A second semiconductor contact zone ( 123 ), wherein the second semiconductor contact zone ( 123 ) in contact with the second load contact ( 13 ); A semiconductor drift zone ( 122 ), wherein the semiconductor drift zone ( 122 ) between the first semiconductor contact zone ( 121 ) and the second semiconductor contact zone ( 123 ) and is doped with first dopants of a first conductivity type, wherein the semiconductor drift zone ( 122 ) the first semiconductor contact zone ( 121 ) to the second semiconductor contact zone ( 123 ), wherein the semiconductor device ( 1 ) further comprises: - a trench ( 14 ) extending along an extension direction (Y) from the first semiconductor contact zone (Y). 121 ) to the second semiconductor contact zone ( 123 ), into the semiconductor region ( 12 ), wherein the trench ( 14 ) a control electrode ( 141 ) and an isolator ( 142 ), wherein the control electrode ( 141 ) in electrical contact with the control terminal ( 17 ) and wherein the insulator ( 142 ) the control electrode ( 141 ) from the semiconductor region ( 12 ), and wherein - the control electrode ( 141 ) within the trench ( 14 ) along the extension direction (Y) at least as far as 75% of the total extent of the semiconductor drift zone ( 122 ) extends in the extension direction (Y); The semiconductor drift zone ( 122 ) has a drift zone doping concentration of first dopants, the drift zone doping concentration and the total extension of the semiconductor drift zone ( 122 ) a reverse voltage of the semiconductor device ( 1 ), - the insulator ( 142 ) is designed to insulate a voltage that is at least 50% of the reverse voltage. Method for controlling a semiconductor device ( 1 ), wherein the semiconductor device ( 1 ) a first load contact ( 11 ), a second load contact ( 13 ) and a semiconductor region ( 12 ) between the first load contact ( 11 ) and the second load contact ( 13 ), wherein the semiconductor region ( 12 ) Includes: a first semiconductor contact zone ( 121 ), wherein the first semiconductor contact zone ( 121 ) in contact with the first load contact ( 11 ); A second semiconductor contact zone ( 123 ), wherein the second semiconductor contact zone ( 123 ) in contact with the second load contact ( 13 ); A semiconductor drift zone ( 122 ), wherein the semiconductor drift zone ( 122 ) between the first semiconductor contact zone ( 121 ) and the second semiconductor contact zone ( 123 ) and is doped with first dopants of a first conductivity type, wherein the semiconductor drift zone ( 122 ) the first semiconductor contact zone ( 121 ) to the second semiconductor contact zone ( 123 ), wherein the semiconductor device ( 1 ) further comprises: - a trench ( 14 ) extending along an extension direction (Y) from the first semiconductor contact zone (Y). 121 ) to the second semiconductor contact zone ( 123 ), into the semiconductor region ( 12 ), wherein the trench ( 14 ) a control electrode ( 141 ) and an isolator ( 142 ), wherein the insulator ( 142 ) the control electrode ( 141 ) from the semiconductor region ( 12 ), and wherein - the control electrode ( 141 ) within the trench ( 14 ) along the extension direction (Y) at least as far as 75% of the total extent of the semiconductor drift zone ( 122 ) extends in the extension direction (Y); The semiconductor drift zone ( 122 ) has a drift zone doping concentration of first dopants, the drift zone doping concentration and the total extension of the semiconductor drift zone ( 122 ) a reverse voltage of the semiconductor device ( 1 ), and wherein the method comprises: providing a gate control signal having a voltage which is at least 50% of the blocking voltage at the control electrode 141 ).

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